Nisin E, a New Nisin Variant Produced by Streptococcus equinus MDC1

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Members of the genus Streptococcus inhabit a variety of sites in humans and other animals and some species are prolific producers of proteinaceous antibiotics (bacteriocins). As little is known about (i) streptococci inhabiting domestic pets, and (ii) whether novel bacteriocin-producing streptococci can be isolated from domestic pets, the aim of this study is to address these gaps in the research literature. In this study, Streptococcus equinus MDC1, isolated from a healthy dog, was found to exhibit potent antibacterial activity against Micrococcus luteus in a simultaneous antagonism assay, suggesting that strain MDC1 produces a lantibiotic bacteriocin. The inhibitory activity spectrum of S. equinus MDC1, determined using agar-based deferred antagonism assays against >70 indicator strains, was found to be similar to that of nisin U (a lantibiotic produced by Streptococcus uberis). However, the spectra of the two bacteriocins differed by 23 strains, mainly with the MDC1 bacteriocin having no inhibitory activity towards certain streptococci of human origin (e.g., Streptococcus gordonii, Streptococcus anginosus, Streptococcus salivarius). The genome of S. equinus MDC1, which was sequenced completely using single-molecule real-time (SMRT) next-generation DNA sequencing technology, comprises a single 1,936,555-basepair chromosome containing seven copies of the ribosomal RNA operon, 69 tRNA genes and nearly 1900 putative coding sequences. Analysis of the MDC1 genome sequence using the bacteriocin detection algorithms BAGEL4 and antiSMASH revealed the location of a 13,164-basepair 11-gene locus, designated nmd, which encoded a mature nisin E peptide that differed from nisin U by only two amino acids (Ile15→Ala and Leu21→Ile) and an extra C-terminal asparagine residue, and the proteins required for post-translational modification of the bacteriocin, processing, export, and producer immunity. Despite the high homology (90.6% identity, 93.8% similarity) between nisin E and nisin U, there was considerably less homology (47.4–76.3% identity, 68.4–88.8% similarity) between the other proteins encoded by their respective biosynthetic loci. This new natural variant of nisin, called nisin E, represents the first nisin variant to be reported for S. equinus; additionally, its differences with nisin U may provide some insight into the amino acids that influence bacteriocin potency and killing spectrum.